BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to switching power supplies of synchronous-rectification LLC resonant converters.
2. Description of the Related Art
Conventionally, switching power supply devices including various types of synchronous-rectification LLC resonant converters have been designed.
FIG. 1 is a circuit diagram of a switching power supply device described in Japanese Unexamined Patent Application Publication No. 2007-274789. The switching power supply device described in Japanese Unexamined Patent Application Publication No. 2007-274789 is an LLC resonant converter. As illustrated in FIG. 1, in the switching power supply described in Japanese Unexamined Patent Application Publication No. 2007-274789, a current transformer is connected in series to an inductor including a primary winding of a transformer, a resonant inductor, and a resonant capacitor. Current flowing to a resonant circuit, that is, current flowing to the primary winding, is detected by the current transformer. The detected current is input to a drive circuit, and the drive circuit controls turning on and off of a secondary-side switching element (synchronization rectification element), on the basis of the detected current.
FIG. 2 is a circuit diagram illustrating a switching power supply device described in Japanese Registered Utility Model No. 3126122. The switching power supply device described in Japanese Registered Utility Model No. 3126122 is a synchronous-rectification LLC resonant converter of a half bridge type. As illustrated in FIG. 2, in the switching power supply device described in Japanese Registered Utility Model No. 3126122, a control circuit is provided on the secondary side. The control circuit controls turning on and off of a primary-side switching element as well as a secondary-side switching element. At this time, after electrical conduction of the primary-side switching element is achieved, the control device allows electrical conduction of the secondary-side switching element when a predetermined time interval (for example, 0.4 microseconds) has passed. Furthermore, after disconnection of the primary-side switching element is achieved, the control device allows disconnection of the secondary-side switching element when a predetermined time interval (for example, 0.15 microseconds) has passed. That is, the control circuit of the switching power supply device described in Japanese Registered Utility Model No. 3126122 controls turning on and off of the primary-side switching element and the secondary-side switching element (synchronization rectification element), with a predetermined time interval between the control for the primary-side switching element and the control for the secondary-side switching element.
As described above, the switching power supply devices described in Japanese Unexamined Patent Application Publication No. 2007-274789 and Japanese Registered Utility Model No. 3126122 control turning on and off of a secondary-side switching element (synchronous rectification element) using different methods. However, in the switching power supply device described in Japanese Unexamined Patent Application Publication No. 2007-274789, in order to drive the secondary-side switching element (synchronous rectification element), a current transformer that detects current of a resonant circuit, that is, current flowing to a primary winding, needs to be provided, thus increasing the number of component elements of the switching power supply device. Furthermore, in order to generate and supply a driving signal for the synchronous rectification element, a high-accuracy, high-speed comparator needs to be provided. Accordingly, the configuration of the switching power supply device becomes complicated, thus generating a problem such as increase in the cost.
Furthermore, as described in Japanese Registered Utility Model No. 3126122, in the configuration in which turning on and off of a primary-side switching element and a secondary-side switching element (synchronous rectification element) is controlled, with a predetermined time interval between the control for the primary-side switching element and the control for the secondary-side switching element, in the case where a switching frequency is lower than the resonant frequency of a resonant circuit, negative current flows when the secondary-side switching element (synchronous rectification element) is turned on. Thus, reverse current toward the primary side may be generated.
SUMMARY OF THE INVENTION
Accordingly, preferred embodiments of the present invention provide a switching power supply device including a resonant converter that does not generate reverse current from a secondary side toward a primary side.
A switching power supply device according to a preferred embodiment of the present invention includes a converter transformer including a primary winding, a first secondary winding, and a second secondary winding; and a series resonant circuit including a resonant inductor and a resonant capacitor that are connected in series with the primary winding. The switching power supply device includes a first switching element and a second switching element that supply electric power to the series resonant circuit by being subject to on/off control in a complementary manner with each other; a third switching element that is connected in series between the first secondary winding and a voltage output terminal; and a fourth switching element that is connected in series between the second secondary winding and the voltage output terminal. The switching power supply device includes a controller that performs PFM control for the first switching element and the second switching element in accordance with output voltage and that controls the third switching element and the fourth switching element. The controller handles a variable A1, which is determined on the basis of a predetermined resonant period, a variable A2, which is generated on the basis of the output voltage and determines a switching period, and a variable A3, which determines turned-on times of the third switching element and the fourth switching element, and determines the turned-on times of the third switching element and the fourth switching element, on the condition that, for a region in which A1 is greater than A2/2, A3 is equal to A2/2, and for a region in which A1 is smaller than or equal to A2/2, A3 is equal to A1.
With this configuration, even when the turned-on time of each of the first switching element and the second switching element on the primary side of the converter transformer is longer than the time based on the predetermined resonant period, the turned-on time of each of the third switching element and the fourth switching element on the secondary side of the converter transformer is limited to the time based on the predetermined resonant period. Accordingly, a situation in which negative current flows in the state in which the third switching element and the fourth switching element on the secondary side are turned on is prevented, and generation of reverse current from the secondary side toward the primary side is prevented.
Furthermore, in the switching power supply device according to a preferred embodiment of the present invention, it is preferable that the predetermined resonant period is half or about half of a resonant period of the series resonant circuit.
With this configuration, even when the turned-on time of each of the first switching element and the second switching element on the primary side of the converter transformer is longer than the time that is half or about half of the resonant period of the series resonant circuit, the turned-on time of each of the third switching element and the fourth switching element on the secondary side of the converter transformer is limited to the time that is half or about half of the resonant period of the series resonant circuit. Accordingly, a situation in which negative current flows in the state in which the third switching element and the fourth switching element on the secondary side are turned on does not occur, and reverse current from the secondary side is not generated.
Furthermore, in the switching power supply device according to a preferred embodiment of the present invention, turning on of the third switching element may be in synchronization with turning on of the first switching element, the third switching element may be turned off by, whichever the earlier, a time at which the second switching element is turned on, or a time after the time half the resonant period of the series resonant circuit has passed since the turning on of the third switching element, turning on of the fourth switching element may be in synchronization with the turning on of the second switching element, and the fourth switching element is turned off by, whichever the earlier, a time at which the first switching element may be turned on, or a time after the time half the resonant period of the series resonant circuit has passed since the turning on of the fourth switching element. Accordingly, a situation in which negative current flows in the state in which the third switching element and the fourth switching element on the secondary side are turned on does not occur, and reverse current from the secondary side is not generated.
Furthermore, the switching power supply device according to a preferred embodiment of the present invention may further include a parallel inductor that is connected in parallel to the primary winding. Accordingly, a second resonant period can be designed using the resonant inductor, the resonant capacitor, and the parallel inductor, current flowing to the transformer is significantly reduced, and heat generation in the transformer is significantly reduced.
Furthermore, in the switching power supply device according to a preferred embodiment of the present invention, it is preferable that the controller includes an MPU that performs the PFM control based on the output voltage, and a driver circuit that generates a driving signal for each of the switching elements, on the basis of driving information for the switching element acquired from the MPU. With this configuration, the controller can be implemented by a digital IC, for example, as much as possible.
Furthermore, for example, the switching power supply device according to a preferred embodiment of the present invention can have the circuit configuration explained below. The first switching element and the second switching element are connected in series between first and second power supply input terminals that define a pair of terminals to which direct current voltage is input. The series resonant circuit is connected in parallel to any one of the first switching element and the second switching element. Accordingly, the primary side of the converter transformer is configured to be a half bridge type. With this configuration, a synchronous-rectification LLC resonant converter of a half bridge type can be implemented.
Furthermore, for example, the switching power supply device according to a preferred embodiment of the present invention may have the circuit configuration explained below. The first switching element and the second switching element are connected in series between first and second power supply input terminals that define a pair of terminals to which direct current voltage is input. A first capacitor and a second capacitor are connected in series between the first and second power supply input terminals, in parallel to a series circuit including the first switching element and the second switching element. By connecting the primary winding and the resonant inductor between a connection point of the first switching element and the second switching element, and a connection point of the first capacitor and the second capacitor, the series resonant circuit is provided. Accordingly, the primary side of the converter transformer is preferably configured to be a half bridge type. With this configuration, a synchronous-rectification LLC resonant converter of a half bridge type is implemented.
Furthermore, for example, the switching power supply device according to a preferred embodiment of the present invention can have the configuration explained below. The first switching element and the second switching element are connected in series between first and second power supply input terminals that define a pair of terminals to which direct current voltage is input. A fifth switching element and a sixth switching element are connected in series between the first and second power supply input terminals, in parallel to a series circuit including the first switching element and the second switching element. By connecting the primary winding and the resonant inductor between a connection point of the first switching element and the second switching element, and a connection point of the fifth switching element and the sixth switching element, the series resonant circuit is provided. Accordingly, the primary side of the converter transformer is configured to be a full bridge type. With this configuration, a synchronous-rectification LLC resonant converter of a full bridge type is implemented.
According to various preferred embodiments of the present invention, since secondary-side switching elements are properly controlled, generation of reverse current from the secondary side toward the primary side is prevented.
The above and other elements, features, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a circuit diagram of a switching power supply device described in Japanese Unexamined Patent Application Publication No. 2007-274789, which is a related art.
FIG. 2 is a circuit diagram of a switching power supply device described in Japanese Registered Utility Model No. 3126122, which is a related art.
FIG. 3 is a circuit diagram of a switching power supply device 100 according to a first preferred embodiment of the present invention.
FIG. 4 is a circuit diagram of a feedback circuit FB in FIG. 3.
FIGS. 5A and 5B are diagrams illustrating a method for generating driving pulses for a first switching element Q1, a second switching element Q2, a third switching element Q3, and a fourth switching element Q4.
FIG. 6 is a waveform chart for explaining control performed in the state in which switching frequency fs is higher than resonant frequency fr.
FIG. 7 is a waveform chart for explaining control performed in the state in which the switching frequency fs is equal to the resonant frequency fr.
FIG. 8 is a waveform chart for explaining control performed in the state in which the switching frequency fs is lower than the resonant frequency fr.
FIG. 9 is a circuit diagram of a switching power supply device 100A of a full bridge type.
FIG. 10 is a circuit diagram of a switching power supply device 100B of a half bridge type.
FIG. 11 is a circuit diagram of a switching power supply device 100C of a half bridge type.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Switching power supplies according to preferred embodiments of the present invention will be described with reference to the drawings.
First Preferred Embodiment
FIG. 3 is a circuit diagram of a switching power supply device 100 according to a first preferred embodiment of the present invention.
The switching power supply device 100 includes power supply input terminals, which are a pair of terminals, connected to a current power supply 200. A first power supply input terminal Pi(+) is provided on a high potential side, and a second power supply input terminal Pi(G) is provided on a ground potential side.
The switching power supply device 100 includes output terminals, which are a pair of terminals connected to load 300. A first output terminal PO(+) is provided on a high potential side, and a second output terminal Po(G) is provided on a ground potential side.
An input capacitor Ci that smoothes input voltage is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G).
A series circuit including a first switching element Q1 and a second switching element Q2, is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G). Here, the series circuit is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G) in such a manner that the first switching element Q1 is arranged on the side of the first power supply input terminal Pi(+) and the second switching element Q2 is arranged on the side of the second power supply input terminal Pi(G).
The first switching element Q1 and the second switching element Q2 are FET switching elements and each include a parasitic capacitor and a body diode.
The drain of the first switching element Q1 is connected to the first power supply input terminal Pi(+), and the source of the first switching element Q1 is connected to the drain of the second switching element Q2. The source of the second switching element Q2 is connected to the second power supply input terminal Pi(G). The gate of each of the first switching element Q1 and the second switching element Q2 is connected to a high side driver 12.
A series circuit including a resonant inductor Lr, a primary winding L1 of a converter transformer T1, and a resonant capacitor Cr is connected in parallel to the second switching element Q2. Furthermore, an excitation inductor Lm is connected in parallel to the primary winding L1. The resonant inductor Lr, the excitation inductor Lm, and the resonant capacitor Cr define a resonant circuit of an LLC resonant converter. The resonant inductor Lr and the excitation inductor Lm may include a leakage inductor of the converter transformer T1 and an excitation inductor or may be configured by connecting inductors in series with or parallel to the primary winding L1, for example.
The converter transformer T1 includes a first secondary winding L21 and a second secondary winding L22 that are magnetically coupled to the primary winding L1, as well as the above-mentioned primary winding L1. The first secondary winding L21 and the second secondary winding L22 are connected to each other so as to have the same polarity with respect to the primary winding L1.
The connection point of the first secondary winding L21 and the second secondary winding L22 is connected to the first output terminal PO(+).
The end portion of the first secondary winding L21 that is opposite to the above-mentioned connection point is connected to the second output terminal Po(G) via a third switching element Q3. Here, the drain of the third switching element Q3 is connected to the first secondary winding L21, and the source of the third switching element Q3 is connected to the second output terminal Po(G). The gate of the third switching element Q3 is connected to a pulse transformer 14. The pulse transformer 14 corresponds to a second insulating signal transmitting device.
The end portion of the second secondary winding L22 that is opposite the above-mentioned connection point is connected to the second output terminal Po(G) via a fourth switching element Q4. Here, the drain of the fourth switching element Q4 is connected to the second secondary winding L22, and the source of the fourth switching element Q4 is connected to the second output terminal Po(G). The gate of the fourth switching element Q4 is connected to the pulse transformer 14.
The third switching element Q3 and the fourth switching element Q4 preferably are FET switching elements and each include a parasitic capacitor and a body diode.
A smoothing output capacitor Co is connected between the first output terminal PO(+) and the second output terminal Po(G).
A feedback circuit FB that detects output voltage and generates a feedback signal is connected in parallel to the output capacitor Co.
FIG. 4 is a circuit diagram of the feedback circuit FB. A series circuit including a shunt regulator SR, a resistor R3, and a light-emitting element of a photo-coupler PC, and a voltage-dividing circuit including resistors R1 and R2, are connected between the first output terminal PO(+) and the second output terminal Po(G). A reference terminal of the shunt regulator SR is provided with divided voltage output from the resistor voltage-dividing circuit including the resistors R1 and R2. A negative feedback circuit including a resistor R11 and a capacitor C11 is provided between a voltage control end and the reference terminal of the shunt regulator SR. One end of a light-receiving element of the photo-coupler PC is connected to a constant voltage Vcc via a resistor R4, and the other end to the GND. The voltage at the connection point of the light-receiving element of the photo-coupler PC and the resistor R4 is input as a feedback voltage VFB to an MPU 11. Although not illustrated specifically, the feedback voltage VFB is input to an AD converter arranged inside the MPU 11.
The feedback circuit FB operates according to the relationship in which the feedback voltage VFB decreases as output voltage of the first output terminal Po(+) the second output terminal Po(G) becomes higher than a set voltage.
The photo-coupler corresponds to a first insulating signal transmitting device.
The MPU 11, which serves as a controller, is connected to the high side driver 12 and a driver 13. The driver 13 is connected to the pulse transformer 14.
The MPU 11 calculates the switching frequency fs of each of a first switching control signal (hereinafter, simply referred to as a first control signal) and a second switching control signal (hereinafter, simply referred to as a second control signal), under PFM (Pulse Frequency Modulation) control, on the basis of the feedback voltage VFB. The first control signal is a control signal to be supplied to the first switching element Q1, and the second control signal is a control signal to be supplied to the second switching element Q2. The MPU 11 supplies the first control signal and the second control signal based on the switching frequency fs to the high side driver 12.
The PFM control represents control to set the switching frequency fs, which is used to control turning on and off of a switching element, to be lower when load is high and setting the switching frequency fs to be higher when load is low.
At this time, the MPU 11 generates the first control signal and the second control signal in the form of rectangular waves having two values, Hi and Low. The MPU 11 outputs the first control signal and the second control signal in such a manner that the first control signal and the second control signal are in the Hi state and the Low state in a complimentary manner with each other. Furthermore, the MPU 11 outputs the first control signal and the second control signal in such a manner that a specific dead time in which both the first control signal and the second control signal enter the Low state occurs at a timing when switching between Hi and Low is performed for the first control signal and the second control signal.
The high side driver 12 amplifies the first control signal and the second control signal output from the MPU 11 so that the first switching element Q1 and the second switching element Q2 is driven. The high side driver 12 supplies the first control signal to the first switching element Q1 and supplies the second control signal to the second switching element Q2.
Turning on and off of the first switching element Q1 is controlled on the basis of the voltage Vgs1 of the first control signal applied to the gate thereof. Turning on and off of the second switching element Q2 is controlled on the basis of the voltage Vgs2 of the second control signal applied to the gate thereof. As described above, since switching between Hi and Low is performed for the first control signal and the second control signal in a complementary manner with each other across a dead time (corresponding to td1 in FIGS. 5, 6, and 7), turning on and off of the first switching element Q1 and the second switching element Q2 is controlled in a complementary manner with each other across a dead time, in which both the first switching element Q1 and the second switching element Q2 are turned off. Here, it is desirable that the turned-on time of the first control signal and the turned-on time of the second control signal are substantially the same.
Furthermore, the MPU 11 supplies to the driver 13 a third switching control signal (hereinafter, simply referred to as a third control signal) and a fourth switching control signal (hereinafter, simply referred to as a fourth control signal) that are synchronized with turning on of the first control signal and the second control signal. The third control signal is a control signal to be supplied to the third switching element Q3, and the fourth control signal is a control signal to be supplied to the fourth switching element Q4.
The driver 13 amplifies the third control signal, which is a signal supplied from the MPU 11 and is turned on in synchronization with the first control signal, and amplifies the fourth control signal, which is turned on in synchronization with the second control signal. The driver 13 outputs the third control signal and the fourth control signal to the pulse transformer 14.
The MPU 11 generates the third control signal and the fourth control signal in such a manner that the turned-on time of each of the third control signal and the fourth control signal is set to a time that is half the resonant period Tr (=1/fr) based on the resonant frequency fr in a case where the switching frequency fs is lower than the resonant frequency fr of the series resonant circuit. The third control signal output from the pulse transformer 14 is applied to the gate of the third switching element Q3. The fourth control signal output from the pulse transformer 14 is applied to the gate of the fourth switching element Q4.
Turning on and off of the third switching element Q3 is controlled on the basis of the voltage Vgs3 of the third control signal applied to the gate thereof. Turning on and off of the fourth switching element Q4 is controlled on the basis of the voltage Vgs4 of the fourth control signal applied to the gate thereof.
Accordingly, turning on and off of the third switching element Q3 is controlled in synchronization with the first switching element Q1 unless the switching frequency fs is lower than the resonant frequency fr of the series resonant circuit. Turning on and off of the fourth switching element Q4 is controlled in synchronization with the second switching element Q2 unless the switching frequency fs is lower than the resonant frequency fr of the series resonant circuit.
In contrast, in the case where the switching frequency fs is lower than the resonant frequency fr of the series resonant circuit, although turning on of the third switching element Q3 is controlled in synchronization with turning on of the first switching element Q1, the third switching element Q3 is turned off at a timing earlier than turning off of the first switching element Q1, that is, when a time that is half the resonant period Tr has passed since the turning on. In the case where the switching frequency fs is lower than the resonant frequency fr of the series resonant circuit, although turning on of the fourth switching element Q4 is controlled in synchronization with turning on of the second switching element Q2, the fourth switching element Q4 is turned off at a timing earlier than turning off of the second switching element Q2, that is, when a time that is half the resonant period Tr has passed since the turning on.
A method of how to generate driving pulses of the first switching element Q1, the second switching element Q2, the third switching element Q3, and the fourth switching element Q4 will now be explained with reference to FIGS. 5A and 5B. Here, setting and operation of a digital PWM module arranged inside the MPU 11 will be explained.
Referring to FIGS. 5A and 5B, CNTR represents a counter whose value increases with every clock cycle. PRD represents a period, which becomes zero when the value of the CNTR reaches the value of the PRD. That is, the PRD determines a switching period. CMPA, CMPB, and CMPC are thresholds for setting time. The CMPA is half the value of the PRD. The CMPB represents a fixed value and is set in such a manner that the period from the time at which the CNTR exhibits zero to the time at which the value of the CNTR reaches the CMPB is half the resonant period Tr. The CMPC represents a value (CMPA+CMPB), which is obtained by adding the CMPB to the CMPA.
Vgs1 represents a gate driving pulse of the first switching element Q1, Vgs2 represents a gate driving pulse of the second switching element Q2, Vgs3 represents a gate driving pulse of the third switching element Q3, and Vgs4 represents a gate driving pulse of the fourth switching element Q4. Vgs1 is set to rise when the value of the CNTR is equal to zero and to fall when the value of CNTR is equal to the CMPA. Vgs2 is set to rise when the value of the CNTR is equal to the CMPA and to fall when the value of the CNTR is equal to the value of the PRD. Vgs3 is set to rise when the value of the CNTR is equal to zero and to fall when the value of the CNTR is equal to the CMPA or the CMPB. Vgs4 is set to rise when the value of the CNTR is equal to the CMPA and to fall when the value of the CNTR is equal to the value of the PRD or the CMPC.
FIG. 5A illustrates the case where the switching frequency fs is higher than the resonant frequency fr of the series resonant circuit. The CMPA is lower than the CMPB, and the value of the PRD is lower than the CMPC. Thus, Vgs1 and Vgs3 rise at the same timing and fall at the same timing. Furthermore, Vgs2 and Vgs4 rise at the same timing and fall at the same timing.
FIG. 5B illustrates the case where the switching frequency fs is lower than the resonant frequency fr of the series resonant circuit. The CMPA is higher than the CMPB, and the value of the PRD is higher than the CMPC. Thus, although Vgs1 and Vgs3 rise at the same timing (zero), Vgs3 falls when the value of the CNTR is equal to the CMPB and Vgs1 falls when the value of the CNTR is equal to the CMPA. Since the CMPB is set in such a manner that the period from the time at which the value of the PRD is equal to zero to the time at which the value of the PRD reaches the CMPB is half the resonant period Tr, Vgs3 falls when the time that is half the resonant period Tr has passed.
In contrast, although Vgs2 and Vgs4 rise at the same timing (CMPA), Vgs4 falls when the value of the CNTR is equal to the CMPC and Vgs2 falls when the value of the CNTR is equal to the value of the PRD. Here, the CMPC is a value (CMPA+CMPB) that is obtained by adding the CMPB to the CMPA, and the time from the CMPA to the CMPC is set to be equal to the time that is half or about half of the resonant period Tr. That is, Vgs4 falls when the time that is half the resonant period Tr has passed.
Control for electric power supply performed by the switching power supply according to this preferred embodiment will now be explained with reference to FIGS. 6, 7, and 8. FIG. 6 is a waveform chart for explaining control performed in the state in which the switching frequency fs is higher than the resonant frequency fr. FIG. 7 is a waveform chart for explaining control performed in the state in which the switching frequency fs is equal to the resonant frequency fr. FIG. 8 is a waveform chart for explaining control performed in the state in which the switching frequency fs is lower than the resonant frequency fr. FIGS. 6, 7, and 8 each illustrate a single switching period. The switching control illustrated in FIG. 6, 7, or 8 is performed continuously.
In each of FIGS. 6, 7, and 8, Vgs1 represents the voltage of the first control signal, Vgs2 represents the voltage of the second control signal, Vgs3 represents the voltage of the third control signal, and the Vgs4 represents the voltage of the fourth control signal. Furthermore, iLr represents resonant current flowing to the resonant inductor Lr, and im represents excitation current flowing to the excitation inductor Lm. Furthermore, ids3 represents drain-source current of the switching element Q3, and ids4 represents drain-source current of the switching element Q4.
(i) In Case Where Switching Frequency fs is Higher Than Resonant Frequency fr (Case Illustrated in FIG. 6)
In the case where the input voltage is higher than the output voltage (in the case where the output voltage ratio is lower than or equal to 1, and here, an output voltage ratio of 1 represents the case where the output voltage is equal to a voltage obtained by rectifying and smoothing, via a transformer, a square wave generated from the input voltage using half bridge), that is, in the case where control is performed such that the switching frequency fs is made higher than the resonant frequency fr, when the switching element Q1 is turned on at a timing T0 in the state in which the switching element Q2 has already been turned off, resonant current iLr having substantially a sine waveform shape of the resonant frequency fr and corresponding to the turned-on time flows to the series resonant circuit (resonant inductor Lr) during a period from the timing t0 to a timing t1 (timing at which the switching element Q1 is turned off). Furthermore, excitation current im increases linearly.
Here, immediately before the timing t0, during a dead time, current having a negative value flowing to the body diode of the switching element Q1 is generated. Thus, at the timing when the switching element Q1 is turned on, the value of the resonant current iLr is not zero but is negative (here, the direction in which current is supplied from the input side represents a positive value).
When the switching element Q1 is turned on, the switching element Q3 is turned on in synchronization with the turning on of the switching element Q1. Accordingly, the drain-source current ids3 having a positive value, having substantially a sine waveform shape of the resonant frequency fr excited by the first secondary winding L21 of the converter transformer T1, and corresponding to the turned-on time flows to the switching element Q3, and the conduction loss at this time is small. Here, a positive value represents current flowing from the source to the drain. In contrast, during this period, since the switching elements Q2 and Q4 are in the turned-off state, the drain-source current ids4 of the switching element Q4 is 0.
Then, during the period from the timing t1, at which the switching element Q1 is turned off, through a dead time td1 to a timing t2, at which the switching element Q2 is turned on, following the resonant current iLr generated in the period from the timing t0 to the timing t1, current flowing in the body diode of the switching element Q2 is continuously applied to the series resonant circuit. Accordingly, after the specific dead time td1 has passed, the resonant current iLr which has a positive value and whose value suddenly decreases flows to the series resonant circuit (resonant inductor Lr) until the timing t2 at which the switching element Q2 is turned on.
In accordance with this, during this period (from t1 to t2), the drain-source current ids3 having a positive value and following the resonant current flowing during the turned-on period of the switching element Q3 flows to the switching element Q3. The value of the drain-source current ids3 becomes 0 at the timing (timing t2) at which the switching element Q2 is turned on.
Then, when the switching element Q2 is turned on at the timing t2, during the period from the timing t2 to a timing t3 (timing at which the switching element Q2 is turned off), resonant current iLr having substantially a sine waveform shape of the resonant frequency fr obtained by inverting the positive/negative of the value of the resonant current generated during the period from the timing t0 to the timing t1 flows to the series resonant circuit (resonant inductor Lr). Furthermore, excitation current im decreases linearly.
During the dead time td1, current flowing to the body diode of the switching element Q2 is generated. Thus, at the timing at which the switching element Q2 is turned on, the resonant current iLr is not 0. As described above, with the use of the circuit configuration according to this preferred embodiment, the primary-side switching elements Q1 and Q2 are caused to perform ZVS (Zero Voltage Switching) operation.
The switching element Q4 is turned on in synchronization with the turning on of the switching element Q2. Accordingly, the drain-source current ids4 having a positive value, having substantially a sine waveform shape of the resonant frequency fr excited by the second secondary winding L22 of the converter transformer T1, and corresponding to the turned-on time flows to the switching element Q4, and the conduction loss at this time is small. In contrast, since the switching elements Q1 and Q3 are in the turned-off state, the drain-source current ids3 of the switching element Q3 is 0.
Then, during the period from the timing t3, at which the switching element Q2 is turned off, through a dead time td2 to a timing t4, at which the switching element Q1 is turned on, following the resonant current iLr generated during the period from the timing t2 to the timing t3, current flowing in the body diode of the switching element Q1 is continuously applied to the series resonant circuit. Accordingly, after the specific dead time td2 has passed, resonant current iLr which has a negative value and whose value suddenly increases flows to the series resonant circuit (resonant inductor Lr) until the timing t4 at which the switching element Q1 is turned on.
In accordance with this, during this period (from t3 to t4), drain-source current ids4 having a positive value following the current flowing during the turned-on period of the switching element Q4 flows to the switching element Q4. The drain-source current ids4 becomes 0 at the timing when the switching element Q1 is turned on.
(ii) In Case Where Switching Frequency fs is Equal to Resonant Frequency fr (Case Illustrated in FIG. 7)
In the case where the input voltage is equal to the output voltage (in the case where the output voltage ratio is 1), that is, in the case where a driving signal is controlled such that the switching frequency fs is made equal to the resonant frequency fr, when the switching element Q1 is turned on at the timing t0 in the state in which the switching element Q2 has already been turned off, resonant current iLr corresponding to turned-on time and having substantially a sine waveform shape of the resonant frequency fr flows to the series resonant circuit (resonant inductor Lr) during a period from the timing t0 to a timing t1A (timing at which the switching element Q1 is turned off). In accordance with this, excitation current im increases linearly. Here, the turned-on time of the switching element Q1 is longer than the above-described case (i), in which the switching frequency fs is higher than the resonant frequency fr.
Here, the switching element Q1 performs a ZVS operation at the timing t0, similar to the case (i).
The switching element Q3 is turned on in synchronization with the turning on of the switching element Q1. Accordingly, the drain-source current having a positive value, having substantially a sine waveform shape of the resonant frequency fr excited by the first secondary winding L21 of the converter transformer T1, and corresponding to the turned-on time flows to the switching element Q3, and the conduction loss at this time is small. In contrast, during this period, since the switching elements Q2 and Q4 are in the turned-off state, the drain-source current ids4 of the switching element Q4 is 0.
Then, during the period from the timing t1A, at which the switching element Q1 is turned off, through the dead time td1 to a timing t2A, at which the switching element Q2 is turned on, electric charge on the parallel capacitor (parasitic capacitance) of the switching element Q2 is first discharged, and the switching element Q2 is then turned on by the body diode.
On the operation conditions that the switching frequency fs should be equal to the resonant frequency fr, the drain-source current ids3 flowing to the switching element Q3 becomes 0 at the timing t1A, and the drain-source current ids4 flowing to the switching element Q4 starts electric conduction at the timing t1A.
Then, when the switching element Q2 is turned on before the resonant current iLr comes to have a negative value, resonant current iLr having substantially a sine waveform shape of the resonant frequency fr obtained by inverting the positive/negative of the value of the resonant current generated during the period from the timing t0 to the timing t1A flows to the series resonant circuit (resonant inductor Lr). Furthermore, excitation current im decreases linearly.
At this time, similar to the case (i), the switching element Q2 performs a ZVS operation at the timing t2A. As described above, with the use of the circuit configuration according to this preferred embodiment, the primary-side switching elements Q1 and Q2 are caused to perform ZVS operation.
The switching element Q4 is turned on in synchronization with the turning on of the switching element Q2. Accordingly, the drain-source current ids4 having a positive value, having substantially a sine waveform shape of the resonant frequency fr excited by the second secondary winding L22 of the converter transformer T1, and corresponding to the turned-on time flows to the switching element Q4, and the conduction loss at this time is small. In contrast, since during this period the switching elements Q1 and Q3 are in the turned-off state, the drain-source current ids3 of the switching element Q3 is 0.
Then, during the period from a timing t3A, at which the switching element Q2 is turned off, through the dead time td2 to a timing t4, at which the switching element Q1 is turned on, electric charge on the parallel capacitor (parasitic capacitance) of the switching element Q1 is first charged, and the switching element Q1 is then turned on by the body diode.
On the operation conditions that the switching frequency fs should be equal to the resonant frequency fr, the drain-source current ids4 flowing to the switching element Q4 becomes 0 at the timing t3A, and the drain-source current ids3 flowing to the switching element Q3 starts electric conduction at the timing t3A.
(iii) In Case Where Switching Frequency fs is Lower Than Resonant Frequency fr (Case Illustrated in FIG. 8)
In the case where the input voltage is lower than the output voltage (in the case where the output voltage ratio is equal to or higher than 1), that is, in the case where a driving signal is controlled such that the switching frequency fs is lower than the resonant frequency fr, when the switching element Q1 is turned on at the timing t0 in the state in which the switching element Q2 has already been turned off, resonant current iLr having substantially a sine waveform shape of the resonant frequency fr flows to the series resonant circuit (resonant inductor Lr) during the period from the timing t0 to a timing t5 (timing when a time that is half the resonant period Tr of the resonant circuit has passed since the timing t0). Furthermore, excitation current im increases linearly. Furthermore, during the period from the timing t5 to a timing t1B (timing at which the switching element Q1 is turned off), current equal to the excitation current im flows. In this case, the turned-on time of the switching element Q1 is longer than the above-mentioned case (ii), in which the switching frequency fs is equal to the resonant frequency fr.
Here, similar to the cases (i) and (ii), the switching element Q1 performs a ZVS operation at the timing t0.
Here, since the turned-on time (T3onmax) of the switching element Q3 is limited to the time that is half the resonant period Tr of the series resonant circuit as described above, even when the switching element Q3 is turned on in synchronization with the switching element Q1, the switching element Q3 is turned off at the above-mentioned timing t5. That is, even if the switching period of the switching element Q1 is longer than the resonant period Tr, the switching element Q3 is turned off, without being in synchronization with the switching element Q1, when the time that is half the resonant period Tr has passed since the timing at which the switching element Q3 is turned on.
The drain-source current ids3 having a positive value, having substantially a sine waveform shape of the resonant frequency fr excited by the first secondary winding L21 of the converter transformer T1 by the resonant current iLr, and corresponding to the turned-on time (half the resonant period Tr) flows to the switching element Q3, and the drain-source current ids3 becomes 0 after the time that is half the resonant period Tr has passed since the turned-on timing (at timing t5).
Then, during the period from the timing t5 at which the switching element Q3 is turned off to the timing t1B at which the switching element Q1 is turned off, following the resonant current iLr generated during the period from the timing t0 to the timing t5, resonant current iLr corresponding to excitation current im flows. This is because the switching element Q1 is not turned off at the timing t5, which is the time when the time that is half the resonant period Tr has passed since the turning on, and new current continues to be supplied from the switching element Q1 to the series resonant circuit by the timing t1B (timing later than t5) determined by the switching period. In accordance with this, during the period from the timing t5 to the timing t1B (timing at which the switching element Q1 is turned off), excitation current im (resonant current iLr) continues to flow as resonant current of a resonant circuit including the series resonant circuit and the excitation inductance Lm.
During this period, since the switching element Q3 is in the turned-off state, the drain-source current ids3 of the switching element Q3 is 0. Accordingly, generation of reverse current from the secondary side toward the primary side via the switching element Q3, which is described as a problem of the related arts, is reliably prevented.
Then, when the switching element Q1 is turned off at the timing t1B, electric charge on the parallel capacitor (parasitic capacitance) of the switching element Q2 is first discharged, and the switching element Q2 is then turned on by the body diode thereof. Furthermore, the drain-source current ids4 flowing in the switching element Q4 starts electric conduction at the timing t1B.
During the period from the timing t2B to the timing t6, resonant current iLr having substantially a sine waveform shape of the resonant frequency fr obtained by inverting the positive/negative of the value of the resonant current generated during the period from the timing t0 to the timing t5 flows to the series resonant circuit (resonant inductor Lr). Furthermore, excitation current im decreases linearly. Furthermore, during the period from the timing t6 to a timing t3B (timing at which the switching element Q2 is turned off), further reduced resonant current iLr flows. In this case, the turned-on time of the switching element Q2 is longer than the above-mentioned case (ii), in which the switching frequency fs is equal to the resonant frequency fr.
Here, the switching element Q2 also performs a ZVS operation at the timing t2B, similar to the cases (i) and (ii).
Here, since the turned-on time (T4onmax) is limited to the time that is half the resonant period Tr as described above even when the switching element Q4 is turned on in synchronization with turning on of the switching element Q2, the switching element Q4 is turned off at the above-mentioned timing t6. That is, even when the switching period of the switching element Q2 is longer than the resonant period Tr, when the time that is half the resonant period Tr has passed since the turned-on timing, the switching element Q4 is turned off, without being in synchronization with turning on of the switching element Q2.
The drain-source current ids4 having a positive value, having substantially a sine waveform shape of the resonant frequency fr excited by the second secondary winding L22 of the converter transformer T1, and corresponding to the turned-on time (time that is half the resonant period Tr) flows to the switching element Q4, and the drain-source current ids4 becomes 0 after the time that is half the resonant period Tr has passed since the turned-on timing (timing t2B) (at timing t6 and later).
Then, during the period from the timing t6 at which the switching element Q4 is turned off to the timing t3B at which the switching element Q2 is turned off, following the resonant current iLr generated during the period from the timing t2B to the timing t6, resonant current iLr corresponding to excitation current im flows. This is because the switching element Q2 is not turned off at the timing t6, which is the timing after the time that is half the resonant period Tr has passed since the turning on of the switching element Q2, and the energy stored in the series resonant circuit continues to be discharged via the switching element Q1 until the timing t3B (timing later than the timing t6), which is determined on the basis of the switching period. In accordance with this, during the period from the timing t6 to the timing t3B (the timing at which the switching element Q2 is turned off), excitation current im (resonant current iLr) continues to flow as the resonant current of the resonant current including the series resonant circuit and the excitation inductance Lm.
During this period, since the switching element Q4 is in the turned-off state, the drain-source current ids4 of the switching element Q4 is 0. Accordingly, generation of reverse current from the secondary side toward the primary side via the switching element Q4, which is described as a problem of the related arts, is reliably prevented.
As described above, with the use of the configuration according to this preferred embodiment, generation of reverse current from the secondary side toward the primary side is reliably prevented even if the switching frequency fs is lower than the resonant frequency fr.
In the preferred embodiment described above, the turned-on time of each of the secondary-side switching elements Q3 and Q4 preferably is set to the time that is half or about half of the resonant period Tr, for example. However, the turned-on time of each of the switching elements Q3 and Q4 may be set to a specific value that is shorter than or equal to the time that is half or about half of the resonant period Tr. More specifically, the turned-on time of each of the switching elements Q3 and Q4 may be set to a specific value that is shorter than or equal to the time that is half or about half of the resonant period Tr for which a variation in a resonant element constant is taken into consideration or may be set to a specific value that is shorter than or equal to the time that is half or about half of the resonant period Tr after the resonant period Tr is measured in a manufacturing process.
Furthermore, the switching element Q3 is not necessarily turned on in synchronization with turning on of the switching element Q1. Similarly, the switching element Q4 is not necessarily turned on in synchronization with turning on of the switching element Q2. Here, currents that should flow from the sources of the switching element Q3 and the switching element Q4 to the drains of the switching element Q3 and the switching element Q4 flow to the body diodes of the switching element Q3 and the switching element Q4.
Furthermore, although the MPU 11 serving as a controller is preferably arranged on the primary side so that a feedback signal is transmitted by the feedback circuit FB from the secondary side toward the primary side in the preferred embodiment described above, the MPU 11 serving as a controller may be arranged on the secondary side. In this case, a control signal for a primary-side switching element may be transmitted from the secondary side to the primary side via an insulating device such as a pulse transformer.
Furthermore, although the example of a switching power supply device of a half bridge type is described in the foregoing preferred embodiment, a switching power supply device of a full bridge type may be used. FIG. 9 is a circuit diagram of a full-bridge switching power supply device 100A. Since the circuit configuration of the secondary side of the converter transformer T1 in the switching power supply device 100A is the same as that of the switching power supply device 100 described above with reference to FIG. 3, only the circuit configuration of the primary side and the configuration of the connection between the MPU 11 and switching elements will be explained.
A series circuit including a first switching element Q1A and a second switching element Q2a is connected between a first power supply input terminal Pi(+) and a second power supply input terminal Pi(G). Here, the series circuit is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G) in such a manner that the first switching element Q1A is arranged on the side of the first power supply input terminal Pi(+) and the second switching element Q2A is arranged on the side of the second power supply input terminal Pi(G).
Furthermore, a series circuit including a fifth switching element Q5A and a sixth switching element Q6A is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G), in parallel to the series circuit including the first switching element Q1A and the second switching element Q2A. The series circuit including the fifth switching element Q5A and the sixth switching element Q6A is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G) in such a manner that the fifth switching element Q5A is arranged on the side of the first power supply input terminal Pi(+) and the sixth switching element Q6A is arranged on the side of the second power supply input terminal Pi(G).
The fifth switching element Q5A and the sixth switching element Q6A, as well as the first switching element Q1A and the second switching element Q2A, preferably are FET switching elements, and each preferably include a parasitic capacitor and a body diode.
The gate of each of the first switching element Q1A, the second switching element Q2A, the fifth switching element Q5A, and the sixth switching element Q6A is connected to a high side driver 12. The high side driver 12 is connected to the MPU 11.
A series circuit including a resonant inductor Lr, a primary winding L1 of a converter transformer T1, and a resonant capacitor Cr is connected between the connection point of the first switching element Q1A and the second switching element Q2A, and the connection point of the fifth switching element Q5A and the sixth switching element Q6A.
With this configuration, the MPU 11 controls turning on and off of the first switching element Q1A and the sixth switching element Q6A in such a manner that the first switching element Q1A and the sixth switching element Q6A are in synchronization with each other. The MPU 11 controls turning on and off of the second switching element Q2A and the fifth switching element Q5A in such a manner that the second switching element Q2A and the fifth switching element Q5A are in synchronization with each other.
The MPU 11 performs control such that turning on and off of the first switching element Q1A and the sixth switching element Q6A and turning on and off of the second switching element Q2A and the fifth switching element Q5A are complementary with each other.
Furthermore, in the case where the switching frequency fs is equal to or higher than the resonant frequency fr, the MPU 11 performs control such that turning on and off of a third switching element Q3A and turning on and off of the first switching element Q1A and the sixth switching element Q6A are in synchronization with each other. In the case where the switching frequency fs is equal to or higher than the resonant frequency fr, the MPU 11 performs control such that turning on and off of the fourth switching element Q4A and turning on and off of the second switching element Q2A and the fifth switching element Q5A are in synchronization with each other.
Furthermore, the MPU 11 is connected to the third switching element Q3A and the fourth switching element Q4A via a pulse transformer 14. In the case where the switching frequency fs is lower than the resonant frequency fr, the MPU 11 controls turning on of the third switching element Q3A in synchronization with turning on of the first switching element Q1A and the sixth switching element Q6A, and controls turning off of the third switching element Q3A after a time corresponding to the time that is half the resonant period Tr has been passed. In the case where the switching frequency fs is lower than the resonant frequency fr, the MPU 11 controls turning on of the fourth switching element Q4A in synchronization with turning on of the second switching element Q2A and the fifth switching element Q5A, and controls turning off of the fourth switching element Q4A after a time corresponding to the time that is half the resonant period Tr has passed.
Also with the above-mentioned configuration and control, reverse current from the secondary side toward the primary side is reliably prevented, similar to the above-described half bridge type.
FIG. 10 is a circuit diagram of a half-bridge switching power supply device 100B. The circuit configuration of the secondary side of the switching power supply device 100B is preferably the same or substantially the same as that of the switching power supply device 100 illustrated in FIG. 3. The configuration of the switching power supply device 100B is different from the configuration of the switching power supply device 100 illustrated in FIG. 3 in that a series circuit including the resonant inductor Lr, the primary winding L1 of the converter transformer T1, and the resonant capacitor Cr is connected in parallel to a high-side switching element in the circuit configuration of the primary side. Also with this configuration, by performing control similar to that of the switching power supply device 100, reverse current from the secondary side toward the primary side is reliably prevented.
FIG. 11 is a circuit diagram of a half-bridge switching power supply device 100C. The circuit configuration of the secondary side of the switching power supply device 100C is preferably the same or substantially the same as that of the switching power supply device 100 illustrated in FIG. 3. The configuration of the switching power supply device 100C is different from the configuration of the switching power supply device 100 illustrated in FIG. 3 in the circuit configuration of the primary side.
A series circuit including the first switching element Q1 and the second switching element Q2 is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G). Here, the series circuit is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G) in such a manner that the first switching element Q1 is arranged on the side of the first power supply input terminal Pi(+) and the second switching element Q2 is arranged on the side of the second power supply input terminal Pi(G).
Furthermore, a series circuit including a first capacitor C1 and a second capacitor C2 is connected between the first power supply input terminal Pi(+) and the second power supply input terminal Pi(G), in parallel to the series circuit including the first switching element Q1 and the second switching element Q2.
A series circuit including the resonant inductor Lr and the primary winding L1 of the converter transformer T1 is connected between the connection point of the first switching element Q1A and the second switching element Q2A, and the connection point of the first capacitor C1 and the second capacitor C2. Also with this configuration, by performing control similar to that of the switching power supply device 100, reverse current from the secondary side toward the primary side is reliably prevented.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.